JP4869324B2 - Radio resource allocation method and related communication apparatus - Google Patents

Abstract

A method of radio resource allocation in a wireless communication system includes allocating radio resource to a plurality of logical channels according to a grant (402), and allowing the plurality of logical channels to use the remaining grant when the grant remains and all the plurality of logical channels having data available for transmission cannot perform resource allocation anymore (404).

Description

  The present invention relates to a radio resource allocation method and related communication apparatus, and more particularly to a method and related communication apparatus for avoiding waste of radio resources in a communication system.

  According to the MAC (Medium Access Control) protocol specification established by 3GPP (3rd Generation Partnership Project), the MAC layer, which is the lower layer of the RLC (Radio Link Control) layer, performs mapping and multiplexing between logical channels and transport channels. It supports various functions such as demultiplexing (multiplexing), demultiplexing (demultiplexing), logical channel prioritization, and transport format selection. The MAC layer exchanges RLC layers and RLC PDUs (Radio Link Control Protocol Data Units, i.e. MAC SDUs (Medium Access Control Service Data Units)) through logical channels, and UL-SCH (Uplink Shared Channel) or DL-SCH ( It exchanges MAC PDUs with the physical layer through a transport channel such as a downlink shared channel.

  At the MAC layer, a logical channel prioritization process is applied each time a new transmission is performed. Each logical channel is provided with a prioritized bit rate (PBR), which is a bit rate such as X bytes / second or Y bytes / second. The logical channel prioritization process ensures that logical channels operate in descending order of priority based on each configured PBR.

  In other words, in the MAC layer logical channel prioritization process, the logical channel transmits data to the MAC layer in 1 TTI (transmission time interval) based on priority, so that high priority data is transmitted early.

  Next, the logical channel prioritization process will be described in detail, and the resource allocation and data transmission process will be described in detail. When a UE (user terminal) performs uplink transmission, the network of the wireless communication system assigns grants to the UE and provides radio resources. This grant is the maximum amount of data that is allowed to be transmitted to the UE. Thereafter, the RRC (Radio Resource Control) layer of the UE assigns priority and PBR to each logical channel, and allocates resources to each logical channel in descending order of priority. The maximum amount of resources allocated to each logical channel must not exceed PBR.

  In addition, the conventional technology provides a PBR token bucket framework in order to calculate the allowable resource amount of a plurality of logical channels. The PBR token bucket framework uses PBR token bucket parameters and PBR token rate. The PBR token bucket parameter indicates the amount of resources allowed to be used for the logical channel, and the PBR token rate indicates the number of bytes added to the PBR token bucket parameter of the logical channel for each TTI.

  The UE executes the PBR token bucket framework every TTI. The PBR token bucket framework adds a PBR token rate to the PBR token bucket parameter to increase the allowable resource amount of the logical channel, and allocates resources to the logical channel in descending order of priority with a PBR token bucket parameter greater than 0. And reducing the PBR token bucket parameter and grant based on the amount of resources allocated to the logical channel.

  In the prior art, when the allowable resource amount of the logical channel is insufficient (that is, the logical channel PBR token bucket parameter is smaller than the data amount), this logical channel is equivalent to the amount of resources available for the logical channel. Only the amount of resources can be allocated. In this case, the PBR token bucket parameter is reduced to 0 (ie there are no resources available for the logical channel) and no more resources can be allocated to the logical channel. Therefore, if all logical channels with transmission data cannot perform resource allocation, these logical channels cannot transmit data even if the grant remains, resulting in a waste of radio resources.

  It should be noted that the RRC layer further provides an MBR (Maximum Bit Rate) corresponding to a GBR (Guarantee Bit Rate) bearer for each logical channel. MBR is a bit rate such as X bytes / second or Y bytes / second, and varies depending on the type of QoS (Quality of Service) service. For example, a VoIP (voice over internet protocol) service is transmitted using a GBR bearer.

  As an example, the RRC layer assigns PBR, MBR, and priority to each logical channel. The logical channel performs resource allocation in descending order of priority based on the set PBR. If the grant remains thereafter, the logical channel performs resource allocation in descending order of priority based on the set MBR. After that, a logical channel with transmission data cannot allocate any more resources even if the grant remains, resulting in a waste of radio resources.

  In addition, in the conventional technique, the allowable resource amount of each logical channel can be calculated using the PBR token bucket framework, and the allowable resource amount of each logical channel can also be calculated using the MBR token bucket framework. The MBR token bucket framework uses MBR token bucket parameters and MBR token rates. The MBR token bucket parameter indicates the amount of resources allowed to be used for the logical channel, and the MBR token rate indicates the number of bytes added to the MBR token bucket parameter of the logical channel for each TTI.

  In the prior art, the UE executes the PBR token bucket framework for each TTI and then executes the MBR token bucket framework. Since the PBR token bucket framework has already been described, it is omitted here. Subsequently, the UE executes the MBR token bucket framework. The MBR token bucket framework adds the MBR token rate to the MBR token bucket parameter, and the MBR token bucket parameter greater than 0 (ie, MBR) if the UE grant remains and there is transmission data on the logical channel. Allocating resources to logical channels in descending order of priority at a token rate) and decreasing MBR token bucket parameters and grants based on the allocated resource amount. Thereafter, a logical channel with transmission data cannot be allocated any more resources even if a grant remains, resulting in a waste of radio resources.

  As described above, the conventional logical channel prioritization process does not disclose the operation method after the UE executes the MBR token bucket framework, so the logical channel can allocate resources even if the grant remains. Can not. In addition, when there is no allowable resource amount in the logical channel (that is, the MBR token bucket parameter is 0), the logical channel cannot perform resource allocation any more even if the UE grant remains, and the radio resource It causes waste.

  Therefore, according to the conventional technique, after executing the PBR and MBR token bucket framework in the UE, a logical channel with transmission data cannot perform resource allocation any more even if a grant remains. Since the resource allocation cannot be performed, the logical channel cannot transmit data, resulting in a waste of radio resources. In addition, when the allowable resource amount of the logical channel is smaller than the transmission data amount, the logical channel requires more resources for transmitting data, and thus the data is transmitted in individual TTIs. This delays PDU uplink transmission and affects the efficiency of the wireless communication system.

  In order to avoid waste of radio resources, the present invention provides a radio resource allocation method and related communication apparatus in a radio communication system.

  The present invention discloses a radio resource allocation method in a radio communication system. The method includes allocating radio resources to a plurality of logical channels based on grants, and if the grants remain and all logical channels with transmission data cannot perform resource allocation, And allowing the use of.

  The present invention further discloses a communication device used in a wireless communication system. The communication device includes a processor that executes a program and a storage device that is coupled to the processor and stores the program. The program allocates radio resources to multiple logical channels based on grants, and multiple logical channels allocate the remaining grants when grants remain and all logical channels with transmitted data cannot perform resource allocation. And allowing it to be used.

  In order to elaborate on the features of such a method and apparatus, specific examples are given and described below with reference to the figures.

  Please refer to FIG. FIG. 1 is an explanatory diagram showing a wireless communication system 10. The wireless communication system 10 is preferably a long-term evolution (LTE) system and generally includes a network and a plurality of UEs. The network and UE shown in FIG. 1 are only used for explaining the structure of the wireless communication system 10. In fact, the network may include multiple base stations, RNCs (Radio Network Controllers) upon request. The UE is a device such as a mobile phone or a computer system.

  Please refer to FIG. FIG. 2 is a block diagram of the communication device 200. The communication device 200 is, for example, a UE of the wireless communication system 10. In order to simplify the description, only the input device 202, output device 204, control circuit 206, processor 208, storage device 210, program 212, and transceiver 214 of the communication device 200 are shown in FIG. In the communication device 200, the control circuit 206 uses the processor 208 to execute the program 212 in the storage device 210 to perform a process, and controls the operation of the communication device 200. The communication device 200 receives a signal input by a user with an input device 202 (for example, a keyboard), and outputs an image and sound with an output device 204 (for example, a monitor or a speaker). The transceiver 214 is used to receive and transmit wireless signals, transmit the received signals to the control circuit 206, and further output the signals from the control circuit 206 wirelessly. In other words, from the point of view of the communication protocol framework, the transceiver 214 is considered part of the first layer, and the control circuit 206 is used to perform the functions of the second and third layers.

  Please refer to FIG. FIG. 3 is an explanatory diagram showing the program 212 shown in FIG. Program 212 includes application layer 300, third layer 302, and second layer 306, and is coupled to first layer 308. The second layer 306 includes two sublayers such as an RLC layer 306a and a MAC layer 306b. The RLC layer 306a transmits messages and packets to the MAC layer 306b through a plurality of logical channels. The RLC layer 306a is used for processing transmission data or control commands such as segmentation and assembling according to QoS. The MAC layer 306b maps each logical channel packet to a common, shared, or dedicated transport channel according to a radio resource allocation command from the third layer 302 (RRC layer), Perform processes such as mapping, multiplexing, format selection, and random access control.

  When allocating resources used for data transmission to the RLC layer 306a, the MAC layer 306b activates a logical channel prioritization process in order to sequentially transmit data of a plurality of logical channels. In this case, in the embodiment of the present invention, in order to avoid waste of resources that occurs when performing radio resource allocation on a plurality of logical channels of the MAC layer 306b and to improve the efficiency of radio communication, the second layer 306 is provided. A radio resource allocation program 320 is provided.

  Please refer to FIG. FIG. 4 is a flowchart of a process 40 according to the present invention. The process 40 is used for data transmission of a logical channel in the UE of the wireless communication system 10. The process 40 can be compiled as a radio resource allocation program 320 and includes the following steps.

Step 400: Start.
Step 402: Assign radio resources to a plurality of logical channels based on grants.
Step 404: Allow a plurality of logical channels to use the remaining grants when a grant remains and all logical channels with transmission data cannot perform resource allocation.
Step 400: End.

  According to the process 40, the MAC layer 306b allocates resources to logical channels based on priority and PBR. The resource amount of each logical channel is limited by PBR. Further, since the grant decreases according to the resource amount allocated to the logical channel, it is the maximum data amount that is allowed to be transmitted to the UE. If the grant remains and there is transmission data on the logical channel, embodiments of the present invention allow multiple logical channels to transmit data in descending order of logical channel priority until the data or grant is exhausted.

  In the process 40, the embodiment of the present invention calculates the allowable resource amount of each logical channel based on the token bucket framework. This token bucket framework uses token bucket values, token rates, and bucket sizes. The token bucket value indicates the allowable resource amount of the logical channel, the token rate indicates the number of bytes added to the token bucket value of the logical channel for each TTI, and the bucket size indicates the maximum allowable resource amount of each logical channel.

  The method of operation of the token bucket framework can be summarized in the following steps.

1. The token bucket value is calculated using the following formula (step 402).
Token bucket value = Min (bucket size, token bucket value + talk rate)
2. Steps 3 and 4 described below are repeated in descending order of logical channel priority (step 402).
3. The resource amount is allocated to the logical channel according to the following formula (step 402).
Min (Grant, token bucket value, amount of data)
4). Decrease the grant and token bucket values based on the amount of resources allocated to the logical channel. The token bucket value is 0 or a negative number (step 402).
5). If the grant remains and there is transmission data on the logical channel, the remaining grant is assigned to the logical channel in descending order of priority until the data or grant is exhausted (step 404).

  As described above, when the grant remains and there is transmission data in the logical channel, the present invention allows allocation of resources to the logical channel even when the token bucket value of the logical channel is less than or equal to 0. To do. In other words, even when the allowable resource amount is insufficient in the current TTI, the logical channel can use resources and transmit data without being limited by the allowable resource amount. As a result, a logical channel with a high priority can transmit data early without waiting for the next TTI, thereby eliminating waste of radio resources, avoiding data segmentation, and improving PDU transmission efficiency. it can.

  Next, resource allocation of logical channels based on the priority and PBR by the process 40 will be described. The UE executes the PBR token bucket framework based on the PBR by the RRC layer. The PBR token bucket framework is used to calculate the allowable resource amount of each logical channel.

  It should be noted that the token bucket framework concept can be applied to the PBR token bucket framework. Each token bucket value corresponds to a PBR token bucket parameter, the token bucket rate corresponds to a PBR token bucket rate, and the bucket size corresponds to a PBR bucket size. Since the operation method of the PBR token bucket framework is similar to the token bucket framework, detailed description thereof is omitted here. What is important is that when there is a grant and there is transmission data in the logical channel, resources can be allocated to the logical channel in the current TTI even if the allowable resource amount of the logical channel is insufficient.

  In other words, according to an embodiment of the present invention, if the grant remains after executing the PBR token bucket framework on the logical channel, and there is transmission data on the logical channel, priority is given until the data or grant is exhausted. Resources can be allocated to logical channels in descending order. In the embodiment of the present invention, the PBR token bucket framework is applied as the concept of the token bucket framework, and it is possible to avoid that the logical channel with the PBR token bucket parameter = 0 cannot transmit data. Therefore, the embodiment of the present invention can prevent waste of resources, improve the speed of data transmission, and enhance communication quality. On the other hand, according to the conventional technique, when there is a grant and there is transmission data in the logical channel, the logical channel PBR token bucket parameter must be set to 0 or more in order to allocate resources. The channel cannot transmit data, and will transmit data after waiting for the next TTI. As a result, data transmission is delayed and communication quality deteriorates.

  According to the process 40, the logical channel of the MAC layer 306b allocates resources based on the priority, PBR, and MBR. The resource amount of each logical channel is limited by PBR and MBR. The UE executes the PBR token bucket framework and then executes the MBR token bucket framework. The operation method of this PBR token bucket framework is performed based on steps 1 to 4 of the above token bucket framework, and the above description may be referred to. Similarly, the token bucket framework concept can be applied to the MBR token bucket framework. Therefore, the logical channel can transmit data and efficiently use radio resources. The token bucket value, token bucket rate, and bucket size correspond to the MBR token bucket parameter, MBR token bucket rate, and MBR bucket size, respectively. Since the operation method of the MBR token bucket framework is similar to the token bucket framework, detailed description thereof is omitted here.

  In summary, if a grant remains and there is transmission data on the logical channel, the embodiment of the present invention allows the use of the remaining grant when the logical channel cannot perform resource allocation, and Avoid wasting. The present invention also provides the concept of a token bucket framework. Even if the allowable resource amount of the logical channel is insufficient, the resource can be allocated to the logical channel for the current TTI, thereby improving the speed and efficiency of data transmission.

  The above are preferred embodiments of the present invention, and do not limit the scope of the present invention. Accordingly, any modifications or changes that can be made by those skilled in the art, which are made within the spirit of the present invention and have an equivalent effect on the present invention, shall belong to the scope of the claims of the present invention. To do.

It is explanatory drawing showing a radio | wireless communications system. It is a block diagram of a communication apparatus. It is explanatory drawing showing the program shown in FIG. 4 is a flowchart of a process according to the present invention.

Claims (14)

A method for assigning radio resources in a radio communication system, comprising:
Allocating radio resources to multiple logical channels based on grants;
Reducing a token bucket value of a first logical channel among the plurality of logical channels according to an amount of resources allocated to the first logical channel;
The grant is left, and when all token bucket values of the plurality of logical channels having transmission data is equal to or smaller than its 0, the steps of the plurality of logical channels are allowed to use the remaining grant A method for assigning radio resources. The token bucket value, the first logical channel in 1TTI prioritized bit rate corresponding to a largest data amount allowed to transmit (transmission time interval): corresponding to (PBR Prioritized bit rate), according to claim 1 Wireless resource allocation method. The method of claim 1 , wherein the token bucket value corresponds to a PBR token bucket parameter. 2. The radio resource allocation method according to claim 1 , wherein the token bucket value corresponds to a maximum bit rate (MBR) corresponding to a maximum data amount allowed to be transmitted in 1 TTI in the first logical channel. . The method of claim 1 , wherein the token bucket value corresponds to an MBR token bucket parameter.   The step of allowing the plurality of logical channels to use a remaining grant allocates resources to the plurality of logical channels in descending order of priority of the plurality of logical channels until either data or grant is exhausted. The radio resource allocation method according to 1. After the first logical channel using the remaining grant, the token bucket value of a first logical channel is decreased in accordance with the remaining grant amount allocated to the first logical channel, radio resource allocation method according to claim 1. A communication device used in a wireless communication system,
A processor for executing the program;
A storage device coupled to the processor for storing the program,
The program is
Allocating radio resources to multiple logical channels based on grants;
Reducing a token bucket value of a first logical channel among the plurality of logical channels according to an amount of resources allocated to the first logical channel;
The grant is left, and when all token bucket values of the plurality of logical channels having transmission data is equal to or smaller than its 0, the steps of the plurality of logical channels are allowed to use the remaining grant Including a communication device. The communication apparatus according to claim 8 , wherein the token bucket value corresponds to a PBR corresponding to a maximum data amount allowed to be transmitted in 1 TTI in the first logical channel. The communication device according to claim 8 , wherein the token bucket value corresponds to a PBR token bucket parameter. The communication apparatus according to claim 8 , wherein the token bucket value corresponds to a maximum bit rate (MBR) corresponding to a maximum amount of data allowed to be transmitted in 1 TTI in the first logical channel. The communication device according to claim 8 , wherein the token bucket value corresponds to an MBR token bucket parameter. The step of allowing the plurality of logical channels to use a remaining grant allocates resources to the plurality of logical channels in descending order of priority of the plurality of logical channels until either data or grant is exhausted. 8. The communication device according to 8 . The communication apparatus according to claim 8 , wherein after the first logical channel uses a remaining grant, a token bucket value of the first logical channel decreases according to a remaining grant amount allocated to the first logical channel.

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